Fast ortho-metalation reactions in binuclear dirhodium compounds

Inorg. Chem. 1992, 31, 1224-1232

1224

Contribution from the Departamento de Qulmica Inorghica, Universitat de Valencia, E-46100Burjassot-Valencia, Spain, and Istituto di Chimica Generale ed Inorganica, Centro di Studio per la Strutturistica Diffrattometrica del CNR, Universitl di Parma, Viale delle Science 78, 1-43100Parma, Italy

Fast Ortho-Metalation Reactions in Binuclear Dirhodium Compounds. Syntheses and Molecular Structures of a Monometalated Compound and Two Doubly Metalated Compounds with Head-to-Head Configurations Pascual Lahuerta,*st Jorge

Maria Angela Pellinghelli,* and Antonio Tiripicchio*,*

Received August 8, 1991 The reactions of Rh2(02CCH3)4(MeOH)2 and triphenylphosphine, in 1:4, 1:2,and 1 :1 molar ratios, have been spectroscopically studied using different reaction conditions. Very reactive intermediate products, Rh2(02CCH3)3[(C6H4)PPh2](H02CCH3)2 (1(HO2CCH3),)and Rh2(02CCH3)3[(C6H4)PPh2] [PPh3](H02CCH3)(2(H02CCH3))have been isolated. The structure of I(H02CCH3) has been determined by X-ray diffraction. Crystal data: space group PI,a = 9.807(6)A, b = 19.822 (10)A, c = 8.476 ( 5 ) (Y = 80.10(2)O,fl = 111.02 (2)’, y = 93.67(2)O,Z = 2, 3374 reflections, R = 0.0289. 1(H02CCH3)2readily reacts with an excess of triphenylphosphine at room temperature to form the already reported doubly metalated compound Rh2(02CCH3)2[(C6H4)PPh2]2(PPh3)2 (3(PPh3)2)with a head-to-tail structure. However under thermal conditions l(H02CCH3)2 (4reacts with excess of triphenylphosphine giving in addition to 3(PPh3)2,Rh2(02CCH3)2[(C6H4)PPh2]2(PPh3)(H02CCH3) (PPh3,H02CCH3)), a doubly metalated compound with the orthometalated ligands in a head-tc-head configuration. The structure of the closely related bis(acetic acid) adduct Rh2(02CCH3)2[(C6H4)PPh2]2(H02CCH3)2 4(H02CCH3),) has been determined by X-ray diffraction. Crystal data: space group C2/c, a = 23.443 (9)A, b = 19.868 (8) c = 20.158 (9)A,j3 = 106.60 (2)”, Z = 8,4873reflections, R = 0.0451. The same mixture of compounds is formed from the reaction of Rh2(02CCH3)4(MeOH)2 and a 4-molexcess of PPh3 in refluxing acetic acid. Para-substituted triarylphosphines P(p-XC6H4),(X = CH,, Cl) behave in a similar way, yielding a mixture of compounds with head-to-tail and head-to-head configurations. The structure of the compound Rh2(02CCH3)21(CIC6H3)P(p-C1C6H4)*]2(HOtCCH3)2 (8(H02CCH3),),having a head-to-head confi@ration, has been determined by X-ray diffraction. Crystal data: space group C2/c, a = 36.063 (9)A,b = 16.558 (6)A, c = 23.531 ( 8 ) A, j3 = 125.34 (2)O, Z = 8, 4316 reflections, R = 0.0525. Two different reaction pathways are proposed to justify this chemical behavior.

x,

a,

Introduction

Scheme I

Very few examples of compounds with orthometalated phosphines bridging a bimetallic unit have been reported in the literature.’S2 After the report that dirhodium tetraacetate and triphenylphosphine react in refluxing acetic acid giving a doubly metalated product2 of composition Rh2(02CCH3)2[(C6H4)PPhz]z(H02CCH3)2,we have been investigating this particular reaction in order to gain insight into the mechanistic aspects. Using the (0-haloary1)phosphines and P(oClC6H4)Ph2,5several intermediates were isolated and structurally characterized. The monometalated Rh2(02CCH3)3[(C6H4)P(~ClC6H4)Ph](H02CCH3)2 was shown to react with P(P’XC&)3, ( X = H , CH3) to selectively give doubly metalated compounds with head-tetail (H-T) structures (111) by using a stoichiometric amount of phosphine or compounds with head-to-head (H-H) structures (IV) by using an excess of phosphine (Scheme I).6 These results have been interpreted by assuming that the orthometalation can occur according to two different reaction pathways. Both pathways involve (i) axial coordination of one phosphine to the dirhodium unit, (ii) rearrangement of the phosphine from axial to equatorial coordination, with partial displacement of one acetate group and (iii) proton transfer from the phenyl ring of the phosphine to the acetate. The rearrangement of the axial phosphine, step ii, can occur from each of two different axial positions, so forming H-T (path A) or H-H compounds (path B). The proposed pathways were supported by the spectroscopic detection in solution of some intermediates. The ortho chlorine atom of the metalated phosphine was suggested to influence the selectivity of these reactions. These observations prompted us to investigate the reaction of Rh2(02CCH3)4(MeOH)2with different para-substituted phosphines P(pXC6H4)3 (X = H, CH3, c1) in order to see if the same intermediate compounds could be observed and if the metalation pathway leading to compounds with head-to-head structures can also occur with non-ortho-functionalizedphosphines. W e report here the preparation and reactivity of two intermediate compounds Rh2(02CCH3)3 [(C6H4)PPh2](HO,CCH,), ( 1 ( H 0 2 C C H 3 ) 2 ) 7 and Rh2(02CCH3)3[(C6H4)PPh21 [PPhJ( H 0 2 C C H 3 ) (2(H02CCH3)),as well as the crystal structure of Universitat de Valencia. *Universit&di Parma.

+/

\;“ 1

IV

L = C H J C O ~ H; CrP? = (C6H4)P(o-CIC6H4)Ph

P = PPhj ;

P-C

P(C6H,)Ph2

I

the first one. W e also present evidence of the two pathways in the reaction of 1 ( H 0 2 C C H & with triphenylphosphine leading (a) Barder, T. J.; Tetrick, S.M.; Walton, R. A,; Cotton, F. A.; Powell, G. L. J . Am. Chem. SOC.1984,106, 1323. (b) Bennett, M. A,; Bhargava, S.K.; Griffths, K.D.; Robertson, G. B. Angew. Chem., Int. Ed. Engl. 1987, 26, 260. (c) Bennett, M. A.; Berry, D. E.; Bhargava, S. K.; Ditzel, E. J.; Robertson, G. B.; Willis, A. C. J . Chem. Soc., Chem. Commun. 1987, 1613. (d) Arnold, D. P.; Bennett, M. A.; Bilton, M. A.; Robertson, G. B. J. Chem. Soc., Chem. Commun. 1982, 115. ( e ) Arnold, D. P.; Bennett, M. A.; McLaughlin, G. M.; Robertson, G. B.; Whittaker, M. J. J . Chem. Soc., Chem. Commun. 1983,32.(f) Arnold, D.P.; Bennett, M. A,; McLaughlin, G. M.; Robertson, G. B. J . Chem. Soc., Chem. Commun. 1983,34. (8) Barcelb, F.; Lahuerta, P.;Ubeda, M. A.; Foces-Foces, C.; Cano, F. H.; Martinez-Ripoll, M. Organometallics 1988, 584. (h) Morrison, E. C.; Tocher, D. A. Inorg. Chim. Acta 1989, 157, 139. Morrison, E. C.; Tocher, D. A. J . Organomet. Chem. 1991, 408, 105. (a) Chakravarty, A. R.; Cotton, F. A.; Tocher, D. A.; Tocher, J. H. Organometallics 1985, 4, 8. (b) Chakravarty, A. R.; Cotton, F. A.; Tocher, D. A. J. Chem. SOC.,Chem. Commun. 1984, 501. Barcelb, F.; Cotton, F. A.; Lahuerta, P.; Llbar, R.; Sanaii, M.; Schwotzer, W.;Ubeda, M. A. Organometallics 1986, 5 , 808. Barcelb, F.; Cotton, F. A,; Lahuerta, P.;Sanaii, M.; Schwotzer, W.; Ubeda, M. A. Organometallics 1987, 6, 1105.

0020-1669/92/1331-1224$03.00/0 0 1992 American Chemical Society

Inorganic Chemistry, Vol. 31, No. 7, 1992 1225

Binuclear Dirhodium Compounds Table 1. List of the Described Comwunds with the Structure Tvw and Axial Ligands

11

111

IV

Syntbesis of 1(H02CCH3),. To 400 mg of Rh2(02CCH3)4(MeOH)2 to doubly metalated compounds with head-to-tail and head-to-head (0.79 mmol) in 120 mL of a hot (5:l) toluene/acetic acid mixture, 207 structures depending on the experimental conditions used; an mg of P(C6H5), (0.79 mmol) dissolved in 10 mL of toluene/CHCl, (1:l) unusually rapid metalation reaction is observed in the presence was added with vigorous stirring. The color of the solution immediately of excess of phosphine. We also report the isolation and the crystal changed from blue to blue-purple. After the solution was refluxed for structure of the compounds Rh2(02CCH3)2[(C6H4)PPh2]20.5 h, the solvent was evaporated under vacuum. The resulting crude oil (H02CCH3)2(4(HO2CCH3),) and Rh2(02CCH3)2[(ClC6H3)Pwas chromatographed in a column (1 X 50 cm)packed with silica gel (p-ClC6H,)2]2(H02CCH3)2(8(H02CCH3),), both having the suspended in hexane. After the column was washed with hexane/ metalated phosphines in a head-to-head configuration. Part of CH2C12/aceticacid (40201). elution with hexane/CH,Cl,/acetic acid these results has been published in a preliminary communication! (40:40:3) separated a purple band. From this fraction, 92 mg (12% yield) of compound 3(HO2CCH1), was isolated (see later). Elution with hexExperimental Section ane/CH2Clz/aceticacid (40:4010) separated a blue band. The solvent

Materials and Procedures. The starting compound Rh2(02CCHl)4(MeOH)z was synthesized by reported method^.^ The phosphines P(P CH$&)] and P(p-C1C6H4),(Strem) and pyridine (Aldrich) were used as purchased. P(C6HS))(Aldrich) was recrystallized from hot ethanol prior to use. All solvents were of analytical grade. Toluene and chloroform were previously distilled and degass&, acetic acid only was degassed before use. Thermal reactions were carried out in an argon atmosphere, using appropriate Schlenk-tube techniques. Silica gel (70-230 mesh, 60 A, Aldrich) was used to pack the chromatography columns. 31PNMR spectra were measured on a Bruker AC-200 FT spectrometer (81.015 MHz), operating at 300 K with broad-band decoupling. For all the measurements, the products were dissolved in CH2C12,using 85% H3P04in D 2 0 as external reference. Table I lists the described compounds with their structural type and identity of the phosphine ligand used. Spectroscopic data, chemical shifts and coupling constants corresponding to the described compounds are listed in Table 11.

( 5 ) Cotton, F. A.; Barcelb, F.; Lahuerta, P.; LIBsar, R.; Pay& J.; Ubeda, M. A. Inorg. Chem. 1988, 27, 1010.

(6) Lahuerta, P.; Pay& J.; Solans, X.; Ubeda, M. A. Inorg. Chem., in press. (7) In the full notation, the number indicates the composition and structure of the Rh2Xs core of the compound, showing the nature of the axial ligands in parentheses; sometimes, a short notation is used for simplicity without including the axial ligands. (8) Lahuerta, P.; Pay& J.; Pellinghelli, M. A.; Peris, E.; Tiripicchio, A. J . Orgunomet. Chem. 1989, 373, CS. (9) Rempel, G. A.; Legzdins, P.; Smith, P.; Wilkinson, G. Inorg. Synth. 1971, 13, 90.

was evaporated and the crude product was redissolved in CHzCI,; addition of hexane precipitated Rh2(02CCH3)3[(C6H,)PPhz](H02CCHl)2 (l(H02CCHl)2) as a blue solid (structure type I, 440 mg, yield 73%). By exchange reactions, the axial acetic acid molecults in compound 1(HOzCCH3),are replaced by H 2 0 or PPhl. The compounds so formed were identified on the basis of the spectroscopicdata (see Table 11). For simplicity they are named as l(L)(L'), L and L' being the axial ligands replacing the acetic acid molecules. Syntbesis of 1(PW3)(H02CCH3). A 200-mg (0.26-mmol) sample of 1(H0zCCHl)2was dissolved in CH2C12 (20 mL). A stoichiometric amount of PPh, (69 mg, 0.26 mmol) was added, and the solution changed to red-brown. Concentration under reduccd pressure and addition of hexane gave 243 mg (96%) of the compound Rh2(02CCHl)3[(C6H4)PPhz](PPhl)(HOzCCHl), of structure type I. Syntbeds of 1(H20),. A 1Wmg sample of compound 1(HO2CCH1), (0.13 mmol) was dissolved in CH,Cl,/hexane (5 mL/5 mL) and the solution was chromatographed (1.5 X 30 cm, silica gel/hexane). After the column was washed with an acetone/hexane (1:lO) mixture, higher polarity solvents (acetone/hexane, 1:l) eluted a blue band, which conConcentained the water adduct Rh2(02CCH,)I[(C6H4)PPh2](H20)2. tration under reduced pressure and addition of hexane yielded a blue powder (structure type I, 86 mg, 97%). Synthesis of l(PPh3)(H20). A 100" sample of 1(H20)2(0.15 mmol) was dissolved in CHzCI,; addition of P(C6H,), (38 mg, 0.15 mmol) produced a color change to red-brown. Concentration under reduced pressure and addition of hexane gave a brown-red solid, compound Rh2(02CCH3)3[(C6H4)PPhz](PPh3)(HzO), which was separated by filtration (structure type I, 129 mg, 95%). Synthesis of 2(HOzCCH3).ad 2(H20). A 100-mg sample of Rh2(02CCH3)4(MeOH)2(0.20 mmol) and 207 mg of PPh, (0.40 mmol) were refluxed in toluene (20 mL) for 1 h in an argon atmosphere. After evaporation to dryness under vacuum, the crude product was chromate

1226 Inorganic Chemistry, Vol. 31, No. 7, 1992 Table 11. 31P(1HJ NMR Data for the Described Compounds@ comoound 6b J(Rh-PI ~(HO~CCHAZ 17.6 150 l(P)(HO2CCH,) 24.1 160 17.8 150 1(H20)2 W(H20) 23.7 157 Z(H02CCHg) 16.0 139 W 2 0 ) 15.7 138 3W02CCHd2 19.3 167 3(Ph 17.0 162 3(H20)2 18.9 161 ~(PY), 21.8 166 WOzCCHJ2 18.2 161 5(P)2 16.2 162 5(H20)2 17.3 158 7(H02CCHp)2 20.4 163 7(Ph 16.7 166 7(H20)2 21.5 159 4(P)(HO2CCH3) 25.3 152 ~(HO~CCH~Z 17.7 151 4(H20)2 21.6 148 ~(P)(HO~CCHI) 23.6 153 ~(HO~CCH~)Z 15.0 149 6(H20)2 16.0 149 W)(HO2CCHJ 23.6 153 17.6 149 ~(HOZCCHJ)~ 17.0 151 8(H20)2

Lahuerta et al.

J(R h-P) 6

... 6 ...

10 10

...

'6

... -9.0 ... -10.4 41.1 41.6

I J(Rh-P)

J(Rh-P)

'J(P-P)

...

...

119

...

... 27 ...

112 187 188

29 5 5

... ...

132

28

7

...

...

...

28

7

...

... ...

124

28

8

...

...

...

12

...

10

-11.9

... ... ...

-15.8

... ... -10.1 ... 3 8 5 3 5 6 3 7 8

5.2

...

...

... 3.7

131

... ...

...

1.6

...

... ...

...

...

...

...

...

...

"Chemical shifts in ppm; coupling constants in Hz. bChemical shift from orthometalated phosphine. 'Compounds of type I, 111, and IV, chemical shift for axial phosphine; compounds of type 11, chemical shift for equatorial phosphine. crystallization in the presence of acetic acid compounds of formulation graphed (1.5 X 30 cm, silica gel/hexane). After elution with acetone/ hexane (1:7), a minor orange band was separated and discarded. InRh2(02CCH,)2[(p-XC6Hp)P(p-XC6H4)2]2(H02CCH3)2 were obtained. creasing the polarity of the solvent mixture (acetone/hexane, 1:4) sepaFor X = CH,, compounds S(H02CCH3)2(type 111,69%. Anal. Calcd rated two bands; the first band contained compound 1(H20)2. The (found) for Rh2P2O8CsOHS4: C, 57.15 (57.45); H, 5.19 (5.03)) and second band, of green color, was concentrated under reduced pressure. 6(H02CCH3)2(type IV, 28%. Anal. Calcd (found) for Rh2P2O8C&&.,: The residue was dissolved in the minimum amount of a 1:l CH2C12/ C, 57.15 (56.89); H, 5.19 (5.20)) were obtained; for X = C1, 7(H02CCH3)2 (type 111, 30%. Anal. Calcd (found) for acetic acid mixture. Addition of hexane yielded Rh2(02CCH3),Rh2P2Cb08CUHx:C, 45.04 (45.51); H, 3.10 (3.42)) and 8(H02CCH3)2 [(C&)PPh2] [PPh3J(HO2CCH,) (2(HO2CCH3)) as a green powder (structure type II,4 mg, 1%). IH NMR (CDCl,, 6): 0.93 (3 H, s), 1.04 (type IV, 65%. Anal. Calcd (found) for Rh&Cl608C~H,6: c , 45.04 (44.63); H, 3.10 (3.31)) were obtained. Exchange reactions of the axial (3 H, s), 1.66 (3 H, s), 2.15 (3 H, s), 6.2-7.5 (29 H, m). I3C NMR acetic acid molecules were achieved in practically quantitative yields by (CDC13,6): 21.4,22.6,23.3,23.8 (CH,, s), 122.0-143.7 (aromatic C-H), 187.6, 183.7, 183.9, 184.1 (COO). The water adduct Rh2(02CCH3),the methods described for 3(H02CCHo)2and 4(H02CCH,),. X-ray Crystpuogrpphy. Approximately prismatic crystals suitable for [(C&)PPh2] [PPh,](H20) (2(H20))was obtained by concentrating the X-ray studies were obtained by slow evaporation of a concentrated fraction from the chromatography and precipitating the product with chloroform/acetic acid solution of the corresponding compound (1 and hexane, in the absence of acetic acid. Synthesis of 3(H02CCH,)2and 4(H02CCH,)2. A 400-mg sample of 4; minor amounts of acetonitrile were also added for 8). A blue-gray Rh2(02CCH3)4(MeOH)2 (0.79 mmol) and 829 mg of PPh, (3.16 mmol) crystal of approximate dimensions 0.20 X 0.25 X 0.33 mm (1) and pink-brown crystals of dimensions 0.25 X 0.25 X 0.35 mm (4) and 0.15 were refluxed in toluene (30 mL) in argon atmosphere for 2 h. After evaporation to dryness under vacuum, the crude product was chromatoX 0.25 X 0.30 mm (8) were used for the analyses. The crystallographic data for 1(H02CCH,)2, 4(H02CCHJ2, and 8(H02CCH3)2are sumgraphed (2 X 30 cm, silica gel/hexane). The column was first washed with CH2C12/hexane(1:l) and was later eluted with mixtures of acemarized in Table 111. Unit cell parameters were determined from the tone/hexane of increasing polarity (from 1:lO to 1:3). A red-orange setting angles of 30 carefully centered reflections, having 12 < B < 17" band, which was collected and stored, eluted first followed by a blue (l), 13 < B < 20" (4), and 23 < B < 33' (8). Data were collected at room temperature (22 "C) on a Siemens AED diffractometer, using band, which was also collected. Elution with acetone/hexane (l:l), niobium-filtered Mo K a (1 and 4) and nickel-filtered Cu Ka radiation separated an additional purple band. The orange-red band was reduced (8) and the B/2B scan type. All reflections with B in the ranges 3-25" to dryness and chromatographed again using the previous method. ( l ) , 2.5-26" (4), and 3-60' (8') were measured; of 5364 (I), 8881 (4) Again, a blue and a purple band were collected after a minor red-orange band was discarded. The four blue and purple bands were recombined and 8547 (8) independent reflections, 3374, having I > 2 4 0 (l), 4873, into one blue and one purple fraction. The purple one was concentrated having I > 341) (4) and 4316, having I > 2 4 ) (8). were considered observed and used in the analysis. The reflections were collected with to dryness under reduced pressure and dissolved in a minimum amount a variable scan speed of 3-12" min-I and a scan width from (0 - 0.6)" of acetic acid/CH2C12 (1:l). Addition of hexane yielded Rh2to (0 + 0.6 0.346 tan 0)" (1 and 4) and from (0 - 0.6)' to (ff 0.6 (02CCHd2[(C6H4)PPh2I2(H02CCH3)2 (YHOZCCH,)~)(structure type 111, determined by X-ray diffraction," 314 mg, 45%). Analogous + 0.142 tan 0)" (8). One standard reflection was monitored every 50 treatment of the blue fraction gave Rh2(02CCH3)2[(C6H4)PPh2]2-measurements; no significant decay was noticed over the time of data collection. The individual profiles were analyzed by following Lehmann (H02CCH,)2 (4(H02CCH,)2) (structure type IV, 307 mg, 45%). Anal. Calcd (found): for Rh2P208CUH42:C, 54.66 (54.45); H, 4.39 (4.35). and Larsen.Io Intensities were corrected for Lorentz and polarization effects. A correction for absorption was applied to (8) (maximum and The axial acetic acid molecule in 3(H02CCH3),and 4(H02CCH,) are exchanged by water using the procedure above described for 1minimum values for the transmission factors were 1.197 and 0.835)." (H02CCH,),; this forms respectively the isomers 3(H20)2and 4(H20)2 Only the observed reflections were used in the structure solution and with the molecular formula Rh2(02CCH3)2[(C6H4)PPh2]2(H20)2. refinement. Compound 3(H02CCH3)2reacts with 2 equiv of PPh, giving Rh2The structures were solved by Patterson and Fourier methods and refined by full-matrix least-squares methods first with isotropic thermal (02CCH3)2[(C6H4)PPh2]2(PPh3)2 (3(PPh3)2). Compound 4parameters and then with anisotropic thermal parameters for all the (H02CCH3)2reacts with 1 equiv of PPh, giving Rh2(02CCH,)2[(C~H~)PP~~~Z(PP~~ (4(PPhd(HOzCCH,)). )(H~ZC~H~) Synthesis of Compounds 5 8 . Doubly metalated compounds of structural types 111 and IV were prepared with the phosphines P(p(10) Lehmann, M. S.; Larsen, F. K.Acra Crymllogr.,Secr. A 1974,30, 580. cH3C6H4),and P@-C1C6H4)3by the method described for PPh,. The (11) Walker, N.; Stuart, D. Acra Crystallogr., Secr. A 1983, 39, 158. reaction times were 1 and 5 h respectively. After chromatography and Ugozzoli, F. Compur. Chem. 1987, 11, 109.

+

+

Inorganic Chemistry, Vol. 31, No. 7, 1992 1227

Binuclear Dirhodium Compounds Table 111. ExDerimental Data for the X-rav Diffraction Studies mol formula mol wt cryst syst space group radiatn a, A

b, A c,

A

a,deg 6, deg 79 deg

v,A3

Z

Dcpldrg cm-’

F(000) cm-l R‘ RWb

p,

1(H02CCH3)2 C28H3I O10PRh2 764.33 triclinic Pi Nb-filtered Mo K a (A = 0.71073 A) 9.807 (6) 19.822 (10) 8.476 (5) 80.10 (2) 111.02 (2) 93.67 (2) 1515 (2) 2 1.675 768 11.75 0.0289 0.0388

4(HOzCCH& 966.57 monoclinic

8(H02CCH3)2 C44H36C1608P2Rh2 1173.24 monoclinic

a / c

a / c

C44H4208P2Rh2

Nb-filtered Mo K a (A = 0.71073 A) 23.443 (9) 19.868 (8) 20.158 (9) 90 106.60 (2) 90 8998 (6) 8 1.427 3920 8.38 0.045 1 0.0605

Ni-filtered Cu Ka (A = 1.541 84 A) 36.063 (9) 16.558 (6) 23.531 (8) 90 125.34 (2) 90 11462 (7) 8 1.360 4688 83.01 0.0525 0.0677

‘ R = Ell~ol - I~cII/CI~ol. bRw tZw(lFoI - I ~ c 1 ) 2 / C ~ ( ~ o ) 2 1 ” 2 ~ non-hydrogen atoms of 1and for all the non-hydrogen atoms except those of the phenyl rings (not the metalated ones) for 4 and 8. Some peaks were found in the final A F map of 8 probably due to the presence of a disordered molecule of acetonitrile of solvation, but it was not possible to find among the peaks an acceptable image of it. The 10 largest peaks, practically of the same height, were introduced as carbon atoms of different occupancy factors, but not refined. Being sure of neither the nature nor the number of molecules, the data for this structure are given without the presence of the solvent. All hydrogen atoms of 1were clearly located in the final A F map and refined isotropically, only the two carboxylic hydrogen atoms of the axial acetic acid molecules of 4 and 8 were located in the AF map and refined isotropically, the remaining ones were placed at their geometrically calculated positions (C-H = 1.00 A) and introduced in the final structure factor calculations. The final cycles of refinement were carried out on the basis of 467 (l), 403 (4) and 457 (8) variables; after the last cycles, no parameters shifted by more than 0.74 (l), 2.02 (4) and 0.52 (8) esd. The largest remaining peak in the final difference map was equivalent to about 0.78 (l),1.05 (4) and 0.94 (8) e/A3. In the final cycles of refinement a weighting scheme, w = K[&(F,) gF2I-l was used; at convergence the K and g values were 0.5178 and 0.0076 for 1, 1.0 and 0.0056 for 4 and 0.4912 and 0.0035 for 8, respectively. The analytical scattering factors, corrected for the real and imaginary parts of anomalous dispersions, were taken from ref 12. All calculations were carried out on the Cray Y-MP8/432 computer of the ‘Centro di Calcolo Elettronico Interuniversitario dell’Italia NordOrientale” (CINECA, Casalecchio Bologna, Italy) and on the Gould Powernode 6040 of the “Centro di Studio per la Strutturistica Diffrattometrica” del CNR, Parma, Italy, using the SHELX-76 and s ~ ~ ~ x Ssystems - 8 6 of crystallographic computer ~r0grams.I~The final atomic coordinates for the non-hydrogen atoms for 1,4, and 8 are given in Tables IV-VI, respectively. The atomic coordinates of the hydrogen atoms are given in Tables SI (l), SI1 (4), SI11 (8);the thermal parameters are given in Tables SIV (l), SV (4), and SVI (8).

+

Results We now have sufficient examples of structurally characterized ortho-metalated dirhodium compound^^-^ to allow the 31P(lH) NMR spectroscopic parameters to be diagnostic of a particular structure. We will summarize the correlation between the spectroscopic data and coordination mode of the phosphorus ligands described elsewhere? 31P(*H) chemical shift values in the range 14-26 ppm correspond to orthemetalated triarylphosphines and are sensitive to the nature of the axial ligand. Non-metalated phosphines occupying equatorial coordination sites appear at lower fields, ca.40-55 ppm, while axially coordinated phosphines appear at higher fields, +5 to -16 ppm. In doubly metalated compounds of type IV, the resonances corresponding to axially coordinated (12) International Tables for X-Roy Crystallography; Kynoch Press: Birmingham, England, 1974; Vol. IV. (13) Sheldrick, G. M.SHELX-76. Program for crystal structure determination. University of Cambridge, England, 1976; SHELXS-86 Program for the solution of crystal structures. University of Gottingen, 1986.

Table IV. Atomic Coordinates @lo4) and Equivalent Isotropic Thermal Parameters (A2 X lo4) with Esd‘s in Parentheses for the Non-Hydrogen Atoms of l(HO,CCH,), atom 4 0 Ylb z/c v Rh(1) 2753 (1) 2963 (1) 1652 (1) 297 (1) io5 ( i j 3013 i i j 703 ( i j 319 i2j 2684 (1) 1876 (1) 2763 (2) 301 (4) -655 (4) 2470 (1) 2705 (2) 418 (13) 2544 (2) -1278 (4) 440 (15) 35 (4) 2802 (3) 3792 (4) 3351 (2) 374 (13) 2671 (4) 373 (3) 3539 (2) 378 (13) 2768 (4) 4026 (2) 508 (5) 449 (15) 377 (4) -853 (5) 3997 (2) 470 (17) 3032 (2) 2498 (5) 5295 (4) 526 (18) 4149 (2) 2663 (8) 5546 (5) 895 (25) -2344 (4) 3275 (2) -415 (5) 573 (19) -2392 (5) 4256 (3) -2176 ( 6 ) 775 (21) 982 (5) 3102 (6) 324 (18) 1684 (2) -165 (5) 2138 (6) 353 (19) 2140 (2) -1521 (6) 2302 (7) 460 (23) 1975 (3) -1729 (6) 3322 (8) 578 (27) 1395 (3) -590 (6) 4266 (8) 536 (25) 944 (3) 770 (6) 1092 (3) 4159 (7) 432 (21) 1212 (7) 2527 (3) -1582 (6) 433 (22) 1117 (8) 633 (26) 2254 (3) -3168 (7) 1627 (5) 384 (22) 3607 (2) 3741 (7) 1752 (6) 591 (26) 4023 (3) 5107 (8) 1593 (6) 416 (22) 4297 (3) -555 (7) 1668 (7) 607 (27) 4993 (3) -1521 (8) 6024 (6) 3516 (3) 3053 (8) 558 (28) 7583 (7) 703 (32) 3428 (4) 4259 (9) -3002 (7) 571 (26) 3746 (4) -1457 (8) -4622 (7) 911 (38) 3816 (5) -2036 (1 1) 1289 (2) 2749 (5) 381 (20) 1344 (7) 1582 (6) 600 (7) 459 (23) 879 (3) 1652 (8) -525 (8) 629 (29) 465 (3) 2904 (10) -885 (8) 721 (37) 448 (3) 4053 (8) -199 (9) 693 (31) 859 (4) 928 (8) 527 (26) 1285 (3) 3992 (6) 4732 (6) 4233 (5) 339 (19) 1607 (2) 5168 (8) 4824 (7) 628 (27) 954 (3) 6583 (8) 6054 (8) 752 (32) 785 (3) 7601 (8) 656 (29) 1266 (4) 6732 (7) 7205 (8) 6142 (7) 670 (28) 1903 (3) 526 (24) 5811 (7) 4918 (6) 2074 (3) ‘Equivalent isotropic V defined as one-third of the trace of the orthogonalized U,j tensor.

phosphines appear at about +5 ppm and are coupled to the two rhodium and to the two phosphorus nuclei of the metalated phosphines; this set of signals can be used as diagnostic for head-tehead configuration. The values of ‘J(Rh-P) for metalated phosphines are in the range 138-167 Hs while for axial phosphines

1223 Inorganic Chemistry, Vol. 31, No. 7, 1992 Table V. Atomic Coordinates (X104) and Isotropic Thermal Parameters (A2 X lo') with Esd's in Parentheses for the Non-Hydrogen Atoms of 4(H02CCH3)2 atom x/a Ylb z/c U Rh(1) 2493 (1) 643 (1) 2177 (1) 303 (2)" 2863 ( i j 335 (2j0 1695 ( i j 2532 i i j 2013 (1) 325 (5)" 1509 (1) 602 (1) 1265 (1) 317 (5)" 2437 (1) 1296 (1) 3142 (2) 409 (16)" 119 (2) 2646 (2) 466 (17)' 3749 (2) 2935 (2) 1055 (2) 2504 (2) 430 (17)" 3435 (2) 710 (2) 2832 (3) 480 (18)" 1780 (2) 3457 (2) 1676 (3) 768 (30)' -419 (3) 2761 (3) 1201 (49)" 1983 (5) 3740 (4) -350 (5) 500 (18)" 3561 (2) 2778 (2) 2564 (2) 1308 (41)" 4481 (3) 3393 (4) 2095 (3) 345 (21)" 2721 (3) 1350 (3) 1040 (3) 368 (21)" 3027 (3) 1744 (3) 1562 (3) 517 (28)" 3519 (4) 1576 (3) 1952 (4) 589 (33)" 3697 (4) 1066 (4) 1844 (4) 587 (30)" 3401 (4) 1326 (4) 689 (4) 485 (26)" 2911 (4) 838 (3) 931 (4) 405 (15) 2013 (3) -260 (3) 1218 (3) 459 (17) 2233 (4) -791 (3) 1608 (3) 597 (21) 2247 (4) -1443 (4) 1397 (4) 2061 (4) -1563 (4) 633 (22) 813 (4) 664 (22) 411 (4) 1853 (4) -1056 (4) 495 (17) 1819 (4) -385 (4) 608 (3) 415 (15) 1265 (3) 982 (3) 965 (3) 538 (19) 614 (4) 652 (4) 730 (3) 773 (26) 908 (5) 334 (4) 80 (5) 117 (5) 778 (27) 1578 (5) 185 (4) 701 (4) 1941 (5) 644 (22) 396 (4) 1287 (4) 482 (17) 1646 (4) 791 (3) 361 (21)" 1361 (3) 2095 (3) 2104 (3) 2052 (3) 365 (22)" 2286 (3) 2172 (3) 476 (23)" 2153 (4) 2925 (3) 1957 (3) 580 (33)" 1617 (4) 3346 (4) 1708 (4) 519 (28)" 947 (4) 3144 (3) 1632 (3) 426 (25)" 812 (3) 2520 (3) 1829 (3) 407 (3) 395 (15) 940 (3) 2107 (3) 497 (18) 339 (4) 1898 (3) 289 (4) 640 (22) -324 (4) 1658 (4) 3 (4) -899 (5) 648 (22) 367 (4) 1641 (4) 601 (20) -834 (4) 1011 (4) 1873 (4) 451 (16) -195 (4) 1297 (4) 2110 (3) 385 (15) 1169 (3) 1539 (3) 3164 (3) 503 (17) 947 (4) 1050 (4) 3502 (3) 852 (4) 617 (21) 1231 (4) 4046 (4) 659 (22) 954 (4) 1872 (4) 4251 (4) 1174 (4) 2359 (4) 680 (23) 3923 (4) 1279 (4) 2193 (4) 495 (17) 3371 (3) 3695 (3) 416 (4) 413 (24)" 2892 (3) 4329 (4) 665 (35)" 3164 (4) 11 (4) 2731 (3) 441 (26)" 1262 (4) 3703 (3) 2866 (5) 730 (37)" 1255 (5) 4367 (3) 1631 (6) 782 (45)' -626 (5) 3218 (5) 1163 (8) 1374 (87)" -1175 (6) 3299 (7) 741 (39)" 4105 (4) 2621 (4) 3139 (4) 4444 (5) 1069 (51)" 3282 (5) 3350 (5) "Equivalent isotropic U defined as one-third of the trace of the orthogonalized Uij tensor.

lower values are usually found. In the compound with structure type 111, the steric crowding produced by the phenyl rings from the metalated phosphines weakens the axial rhodium-phosphorus bond, and broad ,*PNMR signals are absent due to some rapid dissociation occurring in solution. In compounds of trpe I or IV, one axial site is not sterically crowded, and the rhodium-axial phosphorus couplings are usually well resolved. Because of the lability of the axial Rh-L bonds, rapid exchange of ligands occurs in solution, especially during the chromatographic separation. The presence of one molecule of water in an axial position is not easily detected by spectroscopy and in some cases can be assumed according to previous crystallographic identifi~ations?9~ when all the possible ligands, acetic acid, and phosphine are not spectroscopically detected.

Lahuerta et al. Table VI. Atomic Coordinates (X104) and Isotropic Thermal Parameters (A2 X lo4) with Esd's in Parentheses for the Non-Hydrogen Atoms of 8(HO,CCH,h

2022 ( i j 690 (1) 51 (2) 477 (2) 1996 (2) 1789 (2) 4331 (1) 1168 (1) 2222 (1) 1613 (2) 1899 (3) 2516 (2) 2717 (2) 1856 (3) 1613 (3) 2252 (2) 2979 (4) 1016 (4) 1376 (4) 1260 (4) 825 (4) 476 (4) 577 (4) 791 (4) 573 (4) 342 (5) 328 (5) 538 (4) 778 (4) 961 (4) 695 (4) 564 (5) 678 (4) 910 (5) 1060 (4) 2167 (3) 2082 (4) 2042 (4) 2068 (5) 2147 (4) 2195 (4) 2079 (4) 1736 (4) 1630 (4) 1894 (4) 2229 (4) 2338 (4) 2837 (4) 3002 (4) 3446 (5) 3746 (4) 3618 (5) 3160 (4) 1692 (4) 1499 (5) 2806 (4) 3277 (4) 1747 (4) 1742 (5) 2602 (4) 2699 (5)

135 ( i j -306 (3) 2900 (3) -3489 (3) -3027 (2) -2350 (3) -413 (3) -46 (2) -738 (2) 1564 (4) 1428 (4) 1054 (4) 448 (4) 943 (5) 2195 (5) 99 (4) 405 (7) -115 (6) -64 (6) -124 (7) -244 (8) -337 (7) -272 (7) 732 (7) 1262 (7) 1934 (9) 2042 (8) 1530 (8) 870 (7) -1020 (7) -1111 (8) -1894 (8) -2534 (8) -2475 (8) -1686 (7) -1437 (6) -1071 (6) -1587 (7) -2414 (7) -2756 (7) -2274 (7) -1251 (6) -954 (7) -1292 (7) -1936 (7) -2256 (7) -1906 (6) -629 (6) -210 (6) -95 (8) -479 (8) -913 (8) -969 (7) 1818 (7) 2650 (7) 898 (6) 1248 (7) 1595 (9) 1857 (8) 239 (7) 256 (7)

843 ( i j -2020 (2) 1005 (3) 1216 (3) -73 (2) 4240 (2) 4619 (2) 1006 (1) 2245 (1) 1252 (4) 619 (4) 2302 (3) 1661 (3) 2676 (4) 2286 (5) 147 (4) 872 (5) 128 (5) 50 (5) -637 (5) -1171 (6) -1091 (5) -444 (5) 967 (6) 411 (7) 433 (8) 984 (7) 1554 (7) 1540 (6) 1081 (5) 1349 (6) 1410 (7) 1187 (7) 908 (7) 860 (6) 1596 (5) 996 (5) 489 (5) 581 (6) 1176 (6) 1683 (6) 2783 (5) 2822 (6) 3245 (6) 3669 (6) 3643 (6) 3209 (5) 2901 (5) 3541 (5) 4022 (7) 3942 (7) 3366 (7) 2847 (6) 808 (5) 494 (6) 2163 (6) 2630 (6) 2750 (6) 3368 (7) 241 (6) -303 (7)

449 (5j" 1149 (24)' 1663 (40)" 1454 (38)" 1166 (33)' 1280 (36)' 1373 (29)" 509 (17)" 467 (17)' 528 (43)' 586 (54)" 490 (41)" 514 (39)" 619 (53)" 782 (68)' 525 (43)" 1286 (75)' 487 (56)' 518 (61)" 596 (63)" 697 (77)" 763 (69)' 702 (70)" 558 (30) 733 (37) 912 (45) 864 (42) 884 (43) 680 (34) 549 (29) 747 (37) 858 (41) 773 (38) 833 (41) 738 (37) 475 (59)" 492 (64)" 579 (74)' 691 (85)' 692 (80)' 559 (69)' 474 (27) 564 (31) 693 (35) 668 (34) 640 (33) 568 (31) 492 (28) 494 (28) 791 (38) 782 (38) 767 (39) 589 (32) 591 (72)" 787 (90)" 551 (76)' 651 (66)" 610 (78)" 939 ( 1 10)" 553 (75)" 839 (94)"

'Equivalent isotropic U defined as one-third of the trace of the orthogonalized U,, tensor.

Reactivity of Rh2(02CCH3)4(MeOH)2with an Excess of Phosphine P(p-XC,H,), (X = H, CH,, CI). We have reacted Rh2(02CCH3)4(MeOH)2with a 4 molar equiv excess of PPh, in refluxing toluene for 2 h. The 31P('H)NMR spectrum of the solution shows signals centered around 20 ppm, due to metalated phosphines, together with a well-resolved signal centered at ca. 5 ppm. All the observed signals were assigned to the new compound Rh2(02CCH3)2[(C6H4)PPh2],(PPh,)( H02CCH3) (4(PPh3)(H02CCH3)),having the H-H structure, as well as the

Binuclear Dirhodium Compounds

Inorganic Chemistry, Vol. 31, No. 7, 1992 1229

already described2 3(PPh3)2,having the H-T structure. These two compounds were separated by chromatographicmethods and were isolated as acetic acid adducts in ca. 45 yield. The crystal structure of 4(H02CCH3)2confirms that the phosphines are in a head-to-head configuration. The same reaction with the para-substituted triarylphosphines gave analogous doubly metalated compounds in different ratios depending on the phosphine used. The yield of the compound with the head-to-head structure was higher for the less basic phosphine: P@-ClC&4)3 (65%),P ( C ~ H S(45%), )~ P@'CH3C6H4)3 (28%). These values did not change substantially by increasing the excess of phosphine used, but they showed some dependence on the reaction temperature. We found that the reaction rate roughly decreases in the order P@-CH3C6H4)3> P(C6H5), > P@ClC6H4)3* Reactivity of R ~ I ~ ( O ~ C C H ~ ) ~ ( with M~O PPhY H ) ~ We have O(I0) confirmed that rhodium tetraacetate and triphenylphosphine (1:2 molar ratio) react in refluxing acetic acid for 1 h to give Rh2(OICCH~)~[(C~H~)PP~~]Z(H~~CCH~)Z ( ~ ( H O Z C C H ~as) ~the ) only isolable product. The 31P(1H]NMR spectrum of the crude reaction mixture showed additional signals of low intensity, inFigure 1. View of the molecular structure of the complex Rh2(02CCH~)3[(C6H,)PPh2](H02CCH3)2 (1(H02CCH,)2),with the atomic dicating the presence of the monometalated compound Rh2numbering scheme. (~zCCH~)~[(C~H~)PP~ZI(H~ZCCH~)~ ( ~ ( H O Z C C H ~as) ~a) minor reaction product. If an aprotic solvent such as toluene is used, a mixture of three products is obtained, compound 3(H02CCH3)2being the major one. These three compounds were separated by column chromatography and isolated as water adducts. Further recrystallization in the presence of acetic acid gave the adducts with acetic acid 1(H02CCH3), (lo%), Rh2(02CCH3)3[(C6H4)PPh2][PPh3](H02CCH3)(2(H02CCH3)) (l%), and 3(H02CCH3)2 (75%). The 3*PNMR data for these compounds are given in Table 11. Compound 2(H02CCH3) shows one resonance at 16.0 ppm in the *Hi NMR spectrum corresponding with the metalated phosphine and an additional low-field resonance (6 = 41.1 ppm), which is diagnostic of an equatorial-bound phosphorus. This equatorial phosphine, unlike those occupying axial positions, is not exchanged by other ligands during the chromatography; however, the axial acetic acid is easily replaced by water giving 2(H20). Additionally 2(H02CCH3)slowly metalates a t room temperature forming 3(H02CCH3)2. The reaction is considerably COB1 faster if an excess of acetic acid is added. Figure 2. View of the molecular structure of the complex Rh2The reaction of Rh2(02CCH3)4(MeOH)2 with PPh3 in a 1:2 (02CCH1)2[(C6H,)PPh2]2(H02CCH3)2 (4(H02CCH3),), with the atmolar ratio in refluxing chloroform over 90 min gave 1 and 2 in omic numbering scheme. 35% and 5% yields respectively, together with unreacted rhodium acetate. These yields did not improve with longer reaction times formed in approximately equal amounts. in chloroform or with lower reaction temperatures. Molecular Structures of Rh2(02CCH3)3[(C6H,)PPh2]Preparation and Reactivity of Compound 1. When Rhz( H o 2 c a 3 ) 2 (1( H 0 2 C a 3 ) 2 ) 9 m 2 ( 0 2 c a 3 ) d(c6H4) PPh2h(02CCH3)4(MeOH)2and PPh3 (1:l) were thermally reacted in ( H o 2 c a 3 ) 2 , (4(HOzCa3)2), ~~(02c(%)d(~c6b)Pacetic acid, compound 3 and dirhodium tetraacetate were obtained (p-CIC6H4)]2(H02CCH3)2(8(H02CCH3),). Views of the as the main reaction products. We obtained the highest 1:3 structures of 1,4, and 8 are shown in Figures 1-3, respectively. concentration ratio when the phosphine is added to a hot solution Important bond distances and angles of 1 are listed in Table VII; of Rh2(02CCH3)4(MeOH)2 in a (5:l) toluene/acetic acid mixture important bond distances and angles of 4 and 8 are listed and with efficient stirring (seeExperimental Section). These conditions compared in Table VIII, as the structures of the two complexes help to prevent the formation of the bis(phosphine) adduct and are very similar. In the structure of 1, the two Rh atoms are help to facilitate a rapid metalation of the phosphine. From this bridged by three acetate groups and by a triphenylphosphine reaction mixture we isolated 1(H02CCH3)2in fairly good yield metalated in one phenyl ring; two oxygens of two acetic acid (ca. 70%). molecules, occupying the axial positions, complete the slightly The availability of compound 1 in a reasonable yield allowed distorted octahedral coordination [angles in the range 84.0 us to undergo a detailed study of a single metalation process under (1)-96.7 (2)O] around the metals. The value of the Rh-Rh bond very controlled conditions. By reacting 1(H02CCH3)2and tridistance, 2.430 (2) A, falls within the lowest range reported for phenylphosphine in CH2C12or CHC13 solution (1:l molar ratio) dirhodium compounds of comparable structure'& and is slightly one of the axial ligands is readily replaced by phosphine giving longer than that found (2.410 (1) A) in the previously reported 1(PPh3)(H02CCH3).This compound, identified by the 31PNMR monometalated dirhodium complex Rh2(02CCH3)3[(c6H4)P(o' spectrum, gives only 3(H02CCH3)2under thermal conditions. ClC6H4)Ph](H02CCH3)2.6The bridge involving the metalated However 1(H02CCH3)2,in the presence of a 3 molar equiv of PPh3 shows an "envelope" conformation with Rh( 1) deviating by PPh3, metalates immediately at room temperature in chloroform, 0.538 (2) 8, from the mean plane defined by the other four atoms; yielding 3(PPh3)2 As a final experiment we added an excess of triphenylphosphine to a solution of l(H02CCH3)2 in refluxing toluene. In these (14) Cotton, F. A.; Walton, R.A. Multiple Bonds between Metal Atoms; Wiley: New York, 1982: (a) p 311; (b) pp 192-198. conditions compounds 3(PPh3)2and 4(PPh3)(H02CCH3)were

'I"""

Lahuerta et al.

1230 Inorganic Chemistry, Vol. 31, No. 7, 1992

Table VII. Selected Bond Distances (A) and Angles (deg) with Esd's in Parentheses for l(H02CCH3)2 Distances 1.264 (6) 2.430 (2) 0(5)-C(11) 1.259 (7) 2.206 (2) 0(6)-C(11) 1.216 (7) 2.025 (4) 0(7)C(13) 1.313 (8) 2.073 (4) 0(8)-C(13) 2.163 (3) 0(9)-C(15) 1.206 (7) 2.336 (4) 0(10)C(15) 1.313 (9) 2.034 (4) C(l)C(2) 1.402 (6) 2.045 (4) C(l)-C(6) 1.402 (7) 2.218 (4) C(2)-C(3) 1.398 (8) 2.301 (4) C(3)-C(4) 1.366 (8) C(4)-C(5) 1.999 ( 5 ) 1.388 (8) 1.800 (6) C(5)-C(6) 1.378 (9) 1.830 (6) C(7)C(8) 1.504 (9) 1.832 (4) C(9)-C(10) 1.499 (9) 1.268 (6) C(ll)-C(12) 1.490 (7) 1.273 (8) C(13)-C(14) 1.505 (8) 1.493 (9) 1.273 (7) C(15)-C(16) 1.254 (5) Figure 3. View of the molecular structure of the complex Rh2(02CCH,)2[(C1C6H~)P~CIC6H4)12(H02CCH,)z (W02CCH3)z)with the atomic numbering scheme.

it is nearly coplanar with the acetate bridge and almost perpendicular to the other two acetate bridges (the dihedral angles between the mean planes are 4.9 ( l ) , 89.2 (1) and 83.5 (l)', respectively). The Rh(1)-P and Rh(2)-C(2) bond distances, 2.206 (2) and 1.999 (5) A respectively, are comparable to those found in the other monometalated dirhodium complex, 2.209 (2) and 2.026 (7) A.6 The Rh-0 bond trans to the carbon atom, 2.218 (4) A, is longer than that trans to the P atom, 2.163 (3) A, in agreement with the expected order of trans influence of M-C and M-P bonds, and both bonds are much longer than the other four involving acetate ligands [in the range 2.025 (4)-2.073 (4) A]. The rather long Rh-O bond distances involving the axial acetic acid molecules, 2.301 (4) and 2.336 (4) A, are indicative of the high trans effect of the metal-metal bond. The Rh-Rh-Oa,,,l angles, 169.0 (1) and 174.4 (1)O deviate slightly from linearity, unlike the doubly metalated complexes, for which the deviations are significant. This suggests that steric interactions between the non-metalated phenyl rings and the axial ligands are responsible for these deviations.2a The two OH groups of the axial acetic acid molecules interact with the two oxygen atoms of the same bridging acetate, opposite to the metalated bridge, through intramolecular hydrogen bonds [0(8).-*0(5) = 2.705 (5) and 0(10).-0(6) = 2.586 (6) A; 0(8)H(8)0(5) = 168 (8) and 0(10)H(10)0(6) = 169 (9)OI. The doubly metalated complexes 4 and 8 differ only in the phosphine ligands, those of 8 being p-C1 substituted triphenylphosphines, so that their structures are quite comparable. The two Rh atoms are bridged by two acetate groups and by two triphenylphosphine ligands in which metalation has occurred at one of the phenyl rings of each phosphine; as for 1 two oxygens of two acetic acid molecules occupy the axial positions. Because of the presence of the two metalated bridges, the octahedral coordination around the Rh atoms is more distorted than in 1 [angles in the range 79.5 (2)-106.1 (2)O in 4 and 82.1 (3)-102.1 (3)O in 81. The Rh-Rh-OaXial angles, 163.6 (2) and 167.2 (2)O in 4 and 167.4 (2) and 167.6 (2)O in 8, deviate significantly from linearity, in a manner different from that observed in 1. The Rh-Rh bond distances, 2.493 (1) in 4 and 2.51 1 (2) A in 8, are longer than those in 1 in agreement with the values found in the other doubly metalated complexe~.~-~ The two bridges involving the metalated phosphines, in a head-to-head configuration, are nearly perpendicular to one another as well as the two acetate bridges (the dihedral angles between the mean planes are 85.8 (2) and 81.6 (1)O in 4 and 83.0 (1) and 85.6 (1)O in 8). The metalated bridges, as in 1, show "envelope" conformations with Rh( 1) deviating from the mean planes through the other four atoms by 0.693 (1) and 0.761 (1)

O(5)-Rh( 1)-0(7) O(3)-Rh( 1)-0(7) O(3)-Rh( 1)-0(5) O(1)-Rh( 1)-0(7) 0(1)-Rh(l)-0(5) O(1)-Rh( 1)-0(3) P-Rh( 1)-0(7) P-Rh( 1)-0(5) P-Rh( 1)-0(3) P-Rh( 1)-0( 1) Rh(2)-Rh( 1)-0(7) Rh(2)-Rh( 1)-0(5) Rh(2)-Rh( 1)-0(3) Rh(2)-Rh(l)-O( 1) Rh(2)-Rh( 1)-P Rh( 1)-Rh( 2)-C( 2) Rh( l)-Rh(2)-0(9) Rh( 1)-Rh(2)-0(6) Rh( l)-Rh(2)-0(4) Rh( l)-Rh(2)-0(2) 0(9)-Rh(2)-C(2) 0(6)-Rh(2)-C(2) 0(6)-Rh(2)-0(9) 0(4)-Rh(2)-C(2) 0(4)-Rh(2)-0(9) O(4)-Rh( 2)-0(6) 0(2)-Rh(2)